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Improved Dryer Control
Technical White Paper Series
Kenneth C. Hill
President
Kadant Johnson Systems Division
David Vijh
Senior Process Control Engineer
2. © Kadant Johnson 2001-2005. Improved Dryer Control
CONTENTS
Significant improvements in dryer section operation and energy efficiency have been achieved
through the close integration of supervisory control and steam system design. Supervisory con-
trol of all system set points is used to optimize system operation and provide ease of use for the
operators. Steam pressures, flows, and differentials are managed under all machine operating
conditions including sheet breaks, tail threading, grade changes, and start-ups. The control sys-
tem accomplishes this without the need for operator intervention. System designs can be sim-
plified and a very wide operating pressure range is produced. Supervisory control assures that
the dryer operation is consistent for different machine operating conditions and machine crews.
This improved consistency results in better dryer section runnability by producing the same
dryness curve as the sheet progresses through the dryer section.
The concept of an improved dryer control system is to utilize modern control capabilities to pro-
vide supervisory control over the steam control and dryer drainage system. There are many
benefits that can be realized with this approach. Consistent dryer operation is produced over
the entire machine operating range and for every machine operating crew. Drying conditions
are controlled in a manner that produces consistent machine direction sheet moisture, constant
draws, and improved runnability. Upsets such as sheet breaks, grade changes, and wash-ups
are handled efficiently by the control system. This produces improved machine efficiency.
EXECUTIVE SUMMARY
Introduction
Traditional Dryer Drainage
Improved Dryer Control Components
Implementation of Supervisory Control
Pressure Curves
System Limits (Anti-Flooding Strategy)
Differential and Blow-through Adjustment
Sheet Break Control
Grade Changes
Automatic System Start-Up and Shutdown
Press Moisture Indication
Valve and Transmitter Condition Monitoring
System Design
Summary
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3. © Kadant Johnson 2001-2005. Improved Dryer Control
Significant improvements in dryer section operation and energy effi-
ciency have been achieved through the close integration of supervisory
control and steam system design. Supervisory control of all system set
points is used to optimize system operation and provide ease of use for
the operators. Steam pressures, flows, and differentials are managed
under all machine operating conditions including sheet breaks, tail
threading, grade changes, and start-ups.
The control system accomplishes this without the need for operator
intervention. System designs can be simplified and a very wide operat-
ing pressure range is produced. Supervisory control assures that the
dryer operation is consistent for different machine operating conditions
and machine crews. This improved consistency results in better dryer
section runnability by producing the same dryness curve as the sheet
progresses through the dryer section.
Different drying strategies can be used in the wet end “quality zone” to
provide consistent sheet quality and runnability. Dryer pressures are
varied according to a predefined set of pressure curves that ensures
proper wet end sheet temperature graduation.
The operation of the dryer section is trouble free. The operating pa-
rameters are tightly controlled and controller limits are continuously
set. This ensures that no dryer flooding or system problems can occur.
A wider range of operation can be achieved with supervisory control.
The upper and lower operating limits of a system are difficult to main-
tain without continuous adjustment of the system. Operators are un-
able to make these fine adjustments to a traditionally controlled system.
The energy efficiency of the system is optimized. Establishing the
proper system relationships and operating limits minimize venting and
steam waste. Steam is conserved during upset and sheet off conditions.
Significant improvements in the ease of use of the system are achieved.
There is little need for operator adjustment of the system. All system
functions are driven from the moisture gage and the sheet break detec-
tors. When adjustment is necessary, it is done using “Increase Drying /
Decrease Drying” controls. The supervisory control manages all sys-
tem set points based on the operator’s desire to increase or decrease
drying on the machine.
INTRODUCTION
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4. © Kadant Johnson 2001-2005. Improved Dryer Control
Figure 1 shows a typical dryer drainage system for an LWC machine
that utilizes a thermocompressor design. This system is considered to
be a well-designed system by traditional standards. It incorporates
thermocompressors for flexibility, blow-through flow control, individ-
ual control of wet end dryers, and flash steam recovery using a com-
mon collection tank. Control of the system would be through a DCS.
Within this system there are :
35 control valves
32 transmitters
12 pressure loops
3 flow loops
10 differential pressure loops
2 temperature loops
5 level loops
Even though most dryer drainage systems are controlled through a
DCS, the control is typically single loop. The moisture gage would
drive the pressure of the final steam group to control reel moisture.
Generally, it is up to the operator to establish the system set points for
the remaining sections. Occasionally, there are simple relationships
programmed into the DCS to adjust pressures in some of the other sec-
tions based on the pressure of the moisture control group. It is up to
the operator to adjust all differential pressure and blow-through flow
settings, and monitor all other loops to ensure the operation and set
point is correct.
TRADITIONAL DRYER DRAINAGE
Air
C
B DA
A B C D
Figure 1: Typical LWC Dryer Drainage System
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5. © Kadant Johnson 2001-2005. Improved Dryer Control
The following is expected of the operator in managing the system.
Adjust all system pressures as machine conditions change.
Understand the operating limits of the system.
Understand how the pressure changes affect the interactions within the
system.
Adjust differential pressures as machine conditions change. This requires
knowledge of syphon characteristics.
Manage pressures on grade changes.
Turn dryer pressures and differential pressures down on sheet breaks.
Pressure turndown is a common feature in many DCS systems however
rarely are differential pressures adjusted. Pressure turndown is often
done in a manner that creates instability in the system.
Reset dryer pressures following a sheet break.
Start the system up following a shutdown.
Know when valves are not positioning correctly.
Know when the system is not operating properly.
Because of the complexity, most of the above operator responsibilities
are handled inconsistently. A significant factor in dryer operation is the
preferences of different operating crews. Often a different set of operat-
ing set points are used for each operating crew. This leads to inconsis-
tent dryer operation, which is difficult to optimize and improve.
IMPROVED DRYER CONTROL COMPONENTS
The following are the components of an improved dryer control system.
1. Utilize supervisory control to manage all system set points under
all steady state, transitory, and upset conditions.
Supervisory control of all pressures using pressure curves
to control the relationships between sections.
Establish system limits based on continuous analysis of
pressure differences within the system.
Manage blow-through flows and differential pressures.
Provide sheet break turndown of pressure and differential
pressure.
Manage grade changes using drying calculations to estab-
lish pressure ramps and steady state pressure set point.
2. Automatic start-up and shutdown of the system can be provided.
Start-up logic takes control of all valves and steam flows to
control dryer warm-up following a shutdown.
Logic frees up the operators for other duties during the
start-up and shutdown sequence.
The condensate return temperature dictates dryer warm-up
rate.
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6. © Kadant Johnson 2001-2005. Improved Dryer Control
3. The dryer operations are monitored to aid troubleshooting and as-
sess system performance.
Incoming sheet moisture from the press section is continu-
ously indicated based on an energy balance around the sys-
tem.
The energy efficiency of the system is reported in terms of
water evaporation and production rate.
Alarms are sent to the operators when the system is out-of-
limits.
4. Condition of the field devices is continuously monitored.
The actual position of the valves is fed back to the control
system. The actual position is compared to the controller
output. The valve is characterized at start-up to establish
the operating curve and deviations from this curve are
“flagged”.
The integrity of the transmitter signal is continuously
monitored.
IMPLEMENTATION OF SUPERVISORY CONTROL
There are two methods to implement a supervisory control system for
the dryer section: a separate dryer drainage control system can be in-
stalled which is dedicated to the dryer section; or a Supervisory Com-
puter can be added to interface to the DCS controllers.
Figure 2 show the configuration of the dedicated dryer drainage control
system. A controller is installed which is used exclusively for dryer
system control. The workstation interfaces directly to the system con-
troller. The supervisory and regulatory control logic is downloaded
into the controller where it runs independent of the workstation.
The workstation is used as an interface to the controller. All the screens
and interface to the system are configured into the Human Machine
Interface running on the workstation. The dryer drainage workstation
can be networked to an existing DCS. Depending on the DCS, it is pos-
sible to give the operators full view and control of the dryer drainage
workstation screens from the DCS workstations.
Figure 3 shows the configuration with a dedicated supervisory control
computer. Regulatory control functions for the dryer drainage system
are done through the DCS controller. A direct communication link is
made between the DCS controller and the Supervisory Computer. The
Supervisory Computer reads and writes information to the DCS con-
troller to adjust the system set points. In the event of a communications
failure with the supervisory computer, the operators would remain in
control of the system through the DCS, however, they would need to
manually adjust system set points.
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7. © Kadant Johnson 2001-2005. Improved Dryer Control
Network Interface To DCS Is Optional
Air
C
B DA
A B C D
Dryer Drainage
System Controller
Control System Workstation
Supervisory Control Logic
Human Machine Interface
Process Link
Input / Output
Figure 2: Separate dryer drainage control system with optional link to DCS.
Figure 3: Supervisory PC with existing DCS.
Input / Output
DCS
Controllers
Supervisory PC
Supervisory Control Logic
Human Machine Interface
Link Made To
DCS Controllers Regulatory Control Of
Air
C
B DA
A B C D
System In DCS(Read / Write)
Network
Interface to DCS
is Optional
Supervisory
Control can be
taken off-line
from DCS
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8. © Kadant Johnson 2001-2005. Improved Dryer Control
PRESSURE CURVES
The development of pressure curves is a key component of supervisory
control of the dryer section. The pressure curves determine the rela-
tionship between the pressures used in the different steam groups.
The pressure curves are developed using drying formulas, which keep
the dryer temperature response linear with regard to drying capacity.
Linear temperature response, not pressure response, is a key to good
dryer and machine direction sheet moisture control. The linear tem-
perature response provides the same sheet moisture control response
whether the dryers are operating at high or low pressures.
The pressure curves are driven from the moisture control section of the
dryer section. As the moisture control group pressure changes in re-
sponse to a change in machine operating conditions, the steam pres-
sures in all control groups change according to a set of pressure curves.
The moisture control section is driven by the machine’s moisture gage
or can be manually set by the operators. If the operators choose to
manually adjust pressures, they are only required to change the pres-
sure in the moisture control group and all other pressures will be set
accordingly by the supervisory control using the pressure curves. Nor-
mally, two buttons are provided: one for increasing drying and one for
decreasing drying.
The pressure curves provide improved consistency and runnability. As
machine operating conditions change, the dryer pressures are varied in
the same manner each time and for each operating crew. The pressure
curves are developed to keep the machine direction moisture constant
at each section split down the dryer section. This regulates where the
sheet shrinkage occurs and helps to keep the draws consistent as basis
weight and speed changes occur.
The pressure curves are used to keep the system at the most energy effi-
cient operating point. The system can be kept stable, without venting,
over the entire operating range by closely regulating the dryer pressure
relationships.
Normally, a number of sets of pressure curves are built into a supervi-
sory control system. The operators can select the appropriate set of
pressure curves. Typically an aggressive drying strategy would be
used for heavier weight grades and a more passive drying strategy
would be used for lightweight grades.
It is important that the pressure curves be adjustable by mill supervi-
sory personnel. The relationships between the pressure groups can be
fine-tuned by mill personnel to make the system produce the best dryer
operation.
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9. © Kadant Johnson 2001-2005. Improved Dryer Control
SYSTEM LIMITS (ANTI-FLOODING STRATEGY)
Supervisory control can be used to extend the operating range of many
dryer drainage systems. To operate at the extreme low limits of a sys-
tem requires frequent and careful adjustment of system pressures. Op-
erators typically establish safe settings. Dryers are often valved out of
service to produce dryer pressures that are sufficiently high to provide
this safe operating point. Supervisory control can be used to make the
many fine pressure adjustments which are needed to keep the dryers
from flooding at very low pressures. This provides the ability to oper-
ate at very low pressures without having to valve dryers out of service.
As an added safety feature, algorithms can be used which “look” at the
pressure differences available in the system. Controller limits are con-
tinuously set to prevent the system from operating at pressures that
will cause dryer flooding. As an example; if the vacuum level at the
condenser is insufficient to provide good drainage, the lower pressure
operating point of the system will be limited so that dryer flooding will
not occur.
DIFFERENTIAL AND BLOW-THROUGH ADJUSTMENT
In a traditional dryer drainage system, operators typically establish dif-
ferential pressure or blow-through flow settings that produce drainage
under the worst operating condition. These settings are rarely changed.
This means that they are not optimized for all other operating condi-
tions. This leads to steam venting and inefficient system operation for
much of the operating range.
The correct amount of blow-through steam depends on the syphon
type, speed, operating pressure, and condensing load. Supervisory
control can be used to adjust the differential pressure based on these
machine operating parameters. The optimized differential and blow-
through flow settings increase the efficiency of the system by reducing
the steam venting and conserving thermocompressor motive steam use.
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10. © Kadant Johnson 2001-2005. Improved Dryer Control
SHEET BREAK CONTROL
Most dryer drainage systems operate without problems during steady
state operation. They may not have the best efficiency, but they do not
create problems. However, it is during upsets such as sheet breaks that
system problems frequently occur.
Some of the issues that need to be addressed during sheet breaks are:
The dryer must be kept draining efficiently during a break. Many ma-
chines experience dryer loading on sheet breaks because the differential
pressures do not follow the rapid changes in dryer pressures.
The dryer pressures should be reduced to improve tail threading. The
dryer surface temperature during a break should equal the surface tem-
perature with the full sheet on. The amount of turndown will vary de-
pending on the operating pressure.
The dryer pressures need to be ramped down in a controlled fashion dur-
ing a break to keep the system stable and to prevent flooding. Too often
rapid changes in pressure create system problems.
The blow-through steam flow needs to be optimized to prevent excessive
steam waste during sheet breaks.
The dryer pressures need to ramp up in pressure in a controlled manner
once the tail has been established.
The dryers must be capable of handling the high condensing loads that
immediately occur once the sheet has been reestablished.
Once the sheet has been reestablished, the drying conditions should be
stable at the pre-break levels so that first quality moisture is achieved
quickly.
Sheet breaks can be best handled using supervisory control strategy.
The dryer ramp down and ramp up rates are regulated by the supervi-
sory control system. The ramp rates are established to keep the system
stable and the dryers draining during the break. The blow-through
flows and differential pressures are also regulated to minimize the
venting during breaks and to keep the vacuum condenser stable.
GRADE CHANGES
Grade change is another non-steady state condition that is typically not
handled efficiently by traditional dryer drainage control systems.
Grade change strategies vary considerably from mill to mill.
Dryer performance can be improved on grade changes by using the
pressure curves to move the dryer pressure ahead of the moisture gage.
Drying calculations can be used to anticipate the required dryer pres-
sure change that will be required as the basis weight and speed are
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11. © Kadant Johnson 2001-2005. Improved Dryer Control
AUTOMATIC SYSTEM START-UP AND SHUTDOWN
Start-up of the steam system is often an area that is inconsistently han-
dled by operating personnel. The start-up time should be varied de-
pending on how long the machine has been shutdown. If the shut-
down has been short, then the warm-up time for the dryers is less, since
the dryers will still be warm. If the shutdown has been long, then the
time needed for warm-up will be significantly greater. Unfortunately it
is impossible for the operators to know how fast to warm-up the dryers.
If it is done too quickly, there is the potential for bearing failures due to
temperature differences. If it is done too slowly, production is lost.
Supervisory logic can be used to take over complete control of the start-
up and shutdown procedure. This relieves the operators from this re-
sponsibility, allowing them to perform other duties.
Logic is used to control the valve opening to regulate air bleed from the
system, steam input to the system, and pressure ramp up. The tem-
perature of the condensate being returned from the system is used to
determine if the dryers have achieved stable temperatures. Once they
have, the system begins to ramp up pressures.
PRESS MOISTURE INDICATION
The amount of energy used by the dryers is directly related to the
amount of water being evaporated. Supervisory control provides a
“tight” system where the energy flows and pressures are known. A
complete energy balance around the system can be made with a few
flow, temperature, and pressure measurements. This allows the total
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changed. The drying calculations examine drying efficiency prior to the
grade change and recalculate the required drying pressures.
The pressure curves are used to adjust the dryer pressures to follow the
grade change without needing to wait for the moisture gage to make the
adjustment.
This grade change strategy allows grade changes to be made more rapidly
with less potential for sheet breaks due to draw changes caused by im-
proper pressure settings.
12. © Kadant Johnson 2001-2005. Improved Dryer Control
VALVE AND TRANSMITTER CONDITION MONITORING
The steam control and dryer drainage system contains a large number
of valves and transmitters. It is left up to the machine operators and
instrument technicians to determine when valves are not positioning
properly or a bad signal is coming from the transmitters.
Valve problems are the cause of many dryer drainage system control
problems. If valves do not position as expected, then the system cannot
be controlled properly. Poor loop tuning is often used to overcome
valve problems.
“Smart” positioners on the valves can provide feedback of the actual
valve position. Software can be incorporated into the supervisory con-
trol system to characterize the valves when the system is started up.
The actual valve position is compared to the controller output and de-
viations from the characterized curve are flagged. The valve can be
scheduled for maintenance when a poor performing valve is identified.
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energy use to be calculated which provides a direct indication of the
amount of water that is being evaporated. The sheet moisture exiting
the press section can be calculated knowing the amount of water being
evaporated and the machine production conditions.
The on-line indication of sheet moisture leaving the press is a very use-
ful tool in operating the paper machine.
Furnish changes can be identified. Identifying furnish changes will affect
runnability and draws. Knowing that a furnish change has occurred al-
lows the operators to anticipate the effects on machine operation.
Pressing efficiency changes and felt performance can be evaluated. This is
useful in scheduling wash-ups and clothing changes.
Press felt break-in can be monitored to allow normal machine speeds as
quickly as possible.
Drying efficiency changes and dryer problems can be identified. The dryer
“U-factor” and drying rate is continuously calculated based on the evapo-
ration rate. When changes occur, it is easy to determine if it is a dryer
problem or the sheet moisture coming into the dryer section has changed.
13. © Kadant Johnson 2001-2005. Improved Dryer Control 13
SYSTEM DESIGN
Supervisory control can be used with most traditional system designs
provided the system is well designed and is in good condition. Both
traditional cascade and thermocompressor systems can be made to op-
erate in a more efficient, user-friendly manner.
One of the more recent developments is the integration of supervisory
control with the system design. This changes the way systems can be
designed. Less complicated, less costly to install, and more energy effi-
cient system designs are possible.
Figure 4 shows a system design for an LWC machine when supervisory
control is utilized. Some of the key system design features are:
The system has a very wide operating range. Main group pressures from
atmospheric pressures up to the maximum dryer rating are possible.
Pumps from the individual separator stations are eliminated. The conden-
sate can be returned back to the collection tank using pressure differences
within the system. Supervisory control provides the assurance that the
pressure differences always exist.
The piping and installed cost of the system is reduced. There is less piping
and the lengths are shorter.
The vent valves to the condenser from the individual dryer groups are
eliminated. On a break, the blow-through steam is vented through the sys-
tem for maximum steam efficiency.
Very deep vacuum levels are possible in the wet end dryers to control pick-
ing and runnability problems. Wet end dryer pressures of –7 psig are pos-
sible.
Flash steam from the high temperature condensate is utilized in the wet
end dryers. The condensate is returned back to the boiler house at a low
temperature for maximum energy efficiency.
14. © Kadant Johnson 2001-2005. Improved Dryer Control
Figure 4: LWC Machine Design with Supervisory Control
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SUMMARY
The use of supervisory control to manage dryer operations has many
advantages. The dryer operation is optimized for both the steady state
and upset situations. Consistency of operation is achieved for all ma-
chine conditions and operating crews. Energy efficiency is improved
by regulating system set points to match machine speeds and dryer
pressures.
ACKNOWLEDGEMENTS
The authors would like to thank Kadant Johnson for allowing the use of
the Kadant Johnson R&D Center and simulated drying programs.
15. Kadant Johnson is a global leader in the design, manufacture, and
service of dryer drainage systems, rotary joints, syphon systems,
and related equipment for the dryer section of the paper machine. For
more information about Kadant Johnson products and services, email
info@kadant.com or visit www.kadant.com.
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